Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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PRIME MOVER FOR OPERATING AN ELECTRIC MOTOR
BACKGROUND OF THE INVENTION
The present invention relates to electric motors. More specifically, the
invention relates to a method and apparatus for operating ac motors.
A typical oil refinery has a large number of pumps that are driven by
electric motors. Electrical power is typically distributed to the electric
motors via a
power grid. The power grid, in turn, receives electrical power from a remote
utility.
Certain drawbacks are associated with distributing electrical power to the
motors via such a power grid. For instance, the power grid can be expensive to
establish, especially for a large refinery. Additionally, transmission losses
can
occur across the grid while electrical power is being distributed to the
various
motors. Transmission losses can also occur while electrical power is being
transmitted to the power grid from the remote utility. Moreover, distributing
the
electrical power can be unreliable.
Certain problems are also associated with the electric motors. Load
conditions on the electric motor often vary during normal operation. An
electric
motor that is operated at a constant speed will operate efficiently under full
load
conditions, but it will operate inefficiently under part load conditions.
Thus,
inefficient operation due to variable load operation can pose a problem.
Another problem can occur during startup of the electric motor. During
startup, the motor receives an inrush of current. The inrush current is
typically
four to six times the current received during steady state operation.
Consequently, motor power rating is constrained between one-quarter to one-
sixth of the maximum power output of the power grid.
The problems arising from variable load conditions and inrush current may
be overcome by the use of a variable speed drive. The variable speed drive
allows the electric motor to operate more efficiently under part load
conditions.
The variable speed drive also limits the inrush of current during startup.
However,
variable speed drives are typically expensive. Additionally, variable
frequency
drives have internal losses associated with their own operation.
Thus, there is a need to limit inrush current during startup and increase
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efficiency of the electric motor during normal operation, without the use of a
variable speed drive. There is also a need to increase energy savings and
improve the reliability of distributing electrical power to the electric
motors.
SUMMARY OF THE INVENTION
A system according to the present invention includes an electric motor; a
prime mover for generating do electrical power; an inverter for converting the
do
power to ac power; and a controller for causing the inverter to vary at least
one of
frequency and current of the ac power. The ac power is supplied to the
electric
motor. The controller can cause the inverter to drive the electric motor at
variable
speed or torque during motor startup and normal motor operation. Consequently,
motor inrush current can be reduced during motor startup, and motor efficiency
can be improved during normal motor operation. Moreover, the inrush current
can be reduced and the motor efficiency can be increased without the use a
conventional variable speed drive.
A prime mover such as a microturbine generator can be located proximate
the electric motor. The microturbine generator can distribute electrical power
to
the electric motor without a power grid, thereby increasing and energy savings
and improving reliability of distributing the electrical power.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 is a block diagram of a system according to the present invention;
Figure 2 is a flowchart of a method of operating an electric motor, the
method being performed in accordance with the present invention;
Figure 3 is an illustration of a frequency profile of ac power supplied to the
electric motor during startup; and
Figure 4 is an illustration of an alternative embodiment of an inverter for
the system.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Figure 1 shows a system 6 including an electric motor 8 and a prime
mover for supplying electrical power to the electric motor 8. The electric
motor 8
may be part of a device such as a compressor, fan or pump. In an oil refinery,
for
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example, the electric motor 8 of a pump can be an ac induction motor having a
power rating of 100 hp.
In a preferred embodiment of the present invention, the prime mover
includes a microturbine generator 10. The microturbine generator 10 includes a
compressor 12, a turbine 14 and an integrated electrical generator 16. The
electrical generator 16 is cantilevered from the compressor 12. The compressor
12, the turbine 14 and the electrical generator 16 are rotated by a single
common
shaft 18. Although in an alternate embodiment the compressor 12, turbine 14
and
electrical generator 16 can be mounted to separate shafts, the use of the
single
common shaft 18 adds to the compactness and reliability of the microturbine
generator 10. The shaft 18 is supported by self-pressurized air bearings such
as
foil bearings. The foil bearings eliminate the need for a separate bearing
lubrication system and reduce the occurrence of maintenance servicing.
Air entering an inlet of the compressor 12 is compressed. Compressed air
leaving an outlet of the compressor 12 is circulated through cold side air
passages 20 in a recuperator 22. Inside the recuperator 22, the compressed air
absorbs heat from the turbine exhaust waste heat. The heated, compressed air
leaving the cold side of the recuperator 22 is supplied to a combustor 24.
Using
the recuperator 22 to heat the compressed air reduces fuel consumption.
Fuel is also supplied to the combustor 24. Either gaseous or liquid fuel
may be used. In gaseous fuel mode, any suitable gaseous fuel can be used.
Choices of fuel include diesel, flare gas, wellhead natural gas, waste
hydrocarbon fuel streams, gasoline, naphtha, propane, JP-8, methane, natural
gas and other man-made gases.
If gaseous fuel is chosen, the gaseous fuel may be compressed by a fuel
compressor 25 or regulated by a fuel regulator prior to entering the combustor
24. Use of the fuel compressor 25 is preferred if the gas pressure is too low,
while use of a regulator is preferred if the pressure is too high to match the
required pressure. If the microturbine generator 10 is located on-site at an
oil
refinery or gas plant, the fuel of choice may be an off-spec stream that would
otherwise be incinerated and wasted. If located at an oil well, the fuel of
choice
may be solution or casing gas that otherwise may be vented or flared. Flaring
is
wasteful and often does not result in complete combustion of the gas,
resulting in
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an environmental hazard, while a turbine can produce a minimum of bad
emissions while converting the gaseous energy into useful mechanical energy.
A flow control valve 26 controls the flow of fuel to the combustor 24. The
fuel is injected into the combustor 24 by an injection nozzle 25.
Inside the combustor 24 the fuel and compressed air are mixed and
ignited by an igniter 27 in an exothermic reaction. Hot, expanding gases
resulting
from combustion in the combustor 24 are directed to an inlet nozzle 30 of the
turbine 14. The inlet nozzle 30 has a fixed geometry. The hot, expanding gases
resulting from the combustion are expanded through the turbine 14, thereby
creating turbine power. The turbine power, in turn, drives the compressor 12
and
the electrical generator 16.
Turbine exhaust gas is circulated by hot side exhaust passages 32 in the
recuperator 22. Inside the recuperator 22, heat from the turbine exhaust gas
is
transferred to the compressed air in the cold side air passages 20. In this
manner, some heat of combustion is recuperated and used to raise the
temperature of the compressed air prior to combustion. After surrendering part
of
its heat, the exhaust gas exits the recuperator 22. Additional heat recovery
stages could be added onto the power generating system 10.
The generator 16 has a permanent magnet rotor 34 and stator windings
36. The rotor 34 is attached to the shaft 18. When the rotor 34 is rotated by
turbine power generated by the rotating turbine 14, an alternating current is
induced in the stator windings 36. Speed of the turbine 14 can be varied in
accordance with external energy demands placed on the microturbine generator
10. Variations in the turbine speed will produce a variation in the frequency
and
2S power generated by the electrical generator 16.
Typically, the turbine 14 will rotate the rotor 34 at speeds greater than
60,000 rpm. Therefore, the generator 16 will generate ac power at frequencies
above typical grid frequencies (e.g., 50 to 60 Hz). A rectifier 38 rectifies
the high
frequency output of the generator 16 to do power, and the do power is
converted
to grid frequency ac power by an inverter 40. The ac power produced by the
inverter 40 is distributed directly to the electric motor 8.
Transistors 42 of the inverter 40 are commanded to switch on and off and
thereby convert the do power to the ac power. Controlling the switching or
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modulation frequency of the transistors 42 can control the frequency of the ac
power. Controlling the frequency of the ac power, in turn, can control the
speed
of the electric motor 8. Controlling the amplitude or depth of modulation
controls
the output voltage and hence the current to the motor 8.
A controller 46 generates commutation commands that cause the inverter
transistors 42 to modulate the do power. The controller 46 also controls the
modulation frequency of the transistors 42 using, for example, a closed loop
control including a speed regulator and a speed sensor. The speed sensor
generates a feedback signal indicating motor speed. The speed regulator
compares a motor speed command to the measured motor speed and generates
a switching frequency command that controls the modulation frequency.
By properly commanding the inverter transistors 42 to increase or ramp up
frequency of the ac power (and, therefore, the speed of the electric motor 8)
during startup, inrush current to the electric motor 8 can be reduced; The
rate at
which the motor speed is ramped up (and, therefore, the rate at which the
frequency is ramped up) can follow a predetermined profile. Thus, the
controller
46 can use a predetermined profile of speed versus time to generate the motor
speed command. In the alternative, motor current can be measured (by a current
sensor 44, for example) and the controller 46 can ramp up the speed command
at a controlled rate such that the measured motor current does not exceed a
limit.
After the electric motor 8 has reached normal operating conditions (e.g.,
full speed or full load), the inverter transistors 42 can be commanded to vary
the
frequency or current of the ac power to track the load conditions of the
electric
motor 8. For example the break horsepower in a pump varies as the cube of the
speed. Controlling the amplitude or depth of the modulation controls the
amplitude of the ac power. Controlling the voltage applied to the motor will
in turn
control the current or torque of the motor. Hence, reducing the frequency or
the
current of the ac power allows the electric motor 8 to operate more
efficiently
under part load. The motor load may be measured directly by measuring motor
torque, or the motor load may be measured indirectly by measuring motor
current, which provides an indication of motor torque.
Whether the current or frequency is varied will depend upon certain
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process 15 requirements or system parameters. "Process requirements," as
used herein, refers not only to necessary conditions of operation of an
electric
motor, but also to desirable or advantageous conditions of operation. As an
example of a process requirement, a pump might be required to pump liquid out
of a tank and maintain a constant flow discharge rate regardless of the height
of
the fluid in the tank. The speed of the pump would remain constant since flow
is
directly proportional to speed. The controller 46 would use a flow rate
transducer
as a process variable. A set point would be scaled as flow rate but would
actually
be a speed set point. The controller 46 would adjust the frequency of the ac
power supplied to the pump motor. When the tank is full, suction pressure of
the
pump will be high, requiring the least amount of torque to maintain the flow.
The
torque requirement will increase as the level in the tank decreases, and it
will
reach a maximum when the tank is almost empty. The inverter 40 will therefore
deliver the most current when the tank is almost empty and the least current
when the tank is full. Thus, a constant speed, variable current (torque)
control
scheme is preferred given the process requirement associated with pumping
liquid from a tank.
On the other hand, if a constant differential across the pump is required, a
constant torque and a variable speed control scheme is preferred. Motor
current
is held constant and motor speed is varied to maintain the differential
pressure. If
the discharge pressure of the pump increased, the controller 46 increases pump
speed in order to maintain the differential pressure across the pump. The
discharge pressure varies as the square of the speed and the control is
accomplished by increasing the frequency of the ac power and maintaining a
constant current.
The controller 46 also controls the turbine speed by controlling the amount
of fuel flowing to the combustor 24. The controller 46 uses sensor signals
generated by a sensor group to determine the external demands placed upon the
microturbine generator 10 and then controls the fuel valve 26 accordingly. The
sensor group may include various temperature and pressure sensors for
measuring various parameters of the microturbine generator 10. For example,
the sensor group may include a shaft speed sensor and a turbine outlet
temperature sensor.
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Referring additionally to Figure 2, the operation of the electric motor 8 will
now be described. The microturbine generator is started (block 100). A fuel
such
as a waste stream may be used. After the microturbine generator 10 has been
started and as is capable of generating electricity, do power is supplied to
the
inverter 40 (block 102). The inverter frequency is set to zero (block 104), an
output of the inverter 40 is connected to the motor 8 (block 106), and the
inverter
40 is commanded to ramp up the current to a normal operating value (block
108).
The inverter 40 is then commanded to ramp up the frequency from an initial
frequency such as 10 Hz to a desired frequency such as 60 Hz (block 110). An
exemplary ramp is shown in Figure 3. As the frequency is ramped up, the speed
of the electric motor 8 is ramped up too. Thus, inrush current is reduced.
Once the electric motor 8 has reached normal operating conditions (e.g., a
desired speed or a desired operating load), the inverter 40 is commanded to
change the frequency or current in response to process requirements (block
112).
If power demand necessitates, the microturbine generator 10 is preferably
ganged or linked with other prime movers to drive the motor 8 (block 114).
Also,
if the microturbine generator 10 fails to generate power, backup power may be
provided by source 48 such as a local power utility or a backup generator
(block
116). When backup power is needed, a utility breaker 50 is closed manually or
automatically. Ac power from the backup source 48 is rectified by the
rectifier 38,
modulated by the inverter 40 under control of the controller 46, and supplied
to
the electric motor 8. Backup power may also be supplied to the controller 46.
The microturbine generator 10 is "plug and play", requiring little more than
a supply of clean fuel, liquid or gas. It can be completely self-contained in
a
weatherproof enclosure. Resulting is a high power density typified by low
weight
(about a third of the size of a comparable diesel generator) and a relatively
small
footprint (for example, approximately 3 feet by 5 feet by 6 feet high).
Thus disclosed is an invention that, without the use of a conventional
variable speed drive, limits inrush current to an electric motor 8 during
startup
and increases motor efficiency during normal operation of the motor 8.
Eliminating the conventional variable speed drive offers benefits such as
reducing the overall cost of operating the motor 8.
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A prime mover such as a microturbine generator 10 may be located
proximate the electric motor 8. The microturbine generator 10 can distribute
electrical power to the electric motor 8 without a power grid, thereby
increasing
energy savings and improving reliability of distributing the electrical power.
The
power grid can be eliminated or it can be used for backup power.
The invention can supply power independent of utility electric power. This
capability is desirable at a process site that does not have access to utility
power.
Thus, the invention can significantly reduce the capital cost of those
installations
where power line construction would be required to bring utility power to the
process site.
A standalone microturbine generator 10 that already comes packaged with
a controller 46 does not need an additional controller for operating the
electric
motor 8. The controller 46 can perform "double duty." Resulting is a synergy
in
using the microturbine generator 10 in combination with the electric motor 8.
The invention can reduce operating costs by utilizing waste fuel sources to
generate power, or by utilizing commercial fuel to reduce the electrical cost
by
peak shaving.
A process plant will frequently have off specification liquid or gas streams
that are expensive to get rid of. The waste streams would have to be
pressurized to be injected into a plant flare. Thus, energy would be wasted.
Furthermore, flares are notoriously inefficient in converting the waste
streams
into 100% carbon dioxide with low NOx emissions. Therefore, another practical
use of the microturbine generator would be to utilize this waste energy stream
to
produce electrical power. Resulting would be a lower capital cost to dispose
of
the waste stream, and a more environmentally friendly process since the
emissions from the turbine are cleaner than flare emissions.
The present invention is not limited to the specific embodiments disclosed
above. For example, the prime mover is not limited to a microturbine generator
10. Other suitable prime movers include internal combustion engines such as
those that run on gasoline, diesel, natural gas, propane and other fuels;
fuels
cells, such as those using phosphoric acid, molten carbonate, proton exchange
membranes, and solid oxides; and Stirling engines, Brayton cycle engines, wind
turbines and hydroelectric power sources.
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Automatic switching can be employed to allow a grid connection after the
motor has reached full speed and load. A plurality of prime movers can be
"ganged" together to feed a dedicated electric motor. The ganging of prime
movers such as microturbine generators allows for larger motors to be driven
and
controlled.
Utility power can be provided to the system, and the inverter can be
configured to automatically transfer the utility power to a process in the
event the
prime mover fails. Such an inverter 240 is shown in Figure 4. The inverter 240
includes a do power bus 245, a bridge rectifier 241 for rectifying the ac
power
from the generator 16 and placing the rectified power on the do bus 245, and
transistors 42 for modulating the power on the do bus 245 to produce ac power.
The inverter 240 also includes a do diode utility bridge 243 having an output
that
parallels an output of the bridge rectifier 241. Bridge diodes 244 of the
utility
bridge 243 are sourced by utility power. If the voltage of the utility power
is
slightly lower than the voltage on the do bus 245, the diodes 244 of the
utility
bridge 243 will be reversed biased. Therefore, no power will flow from them.
However, should the generator 16 fail, the utility power will seamlessly flow
to the
do bus 245, thereby taking over supplying the power requirements of the
generator 16. Consequently, process reliability is increased by providing
backup
power in the event either the utility power or the prime mover fail.
Therefore, the present invention is not limited to the specific embodiments
disclosed above. Instead, the present invention is construed according to the
claims that follow.
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